Copper is a reddish metal with a face-centered cubic crystal structure. It has high electrical and thermal conductivity and good corrosion resistance. Copper alloys include brasses, which are copper-zinc alloys that have good strength and ductility. Bronzes are copper alloys where the primary alloying element is not zinc or nickel, and include phosphor bronzes and aluminum bronzes. Copper alloys have a variety of applications due to their combinations of properties.

1. Introduction
Copper :
Copper is non-polymorphous metal with face centered cubic lattice (FCC, Fig. 1). Pure copper is
a reddish color, zinc addition produces a yellow color, and nickel addition produces a silver
color. Melting temperature is 1083 °C and density is 8900 kg.m-3, which is three times heavier
than aluminum. The heat and electric conductivity of copper is lower compared to the silver, but
it is 1.5 times larger compared to the aluminum.
Fig. 1. FCC lattice
Properties:
 High electrical conductivity
 High thermal conductivity
 High corrosion resistance
 Good ductility and malleability
 Reasonable tensile strength
Pure copper electric conductivity is used like a basic value for other metals evaluation and
electric conductivity alloys characterization. The pure metal alloying decreased its conductivity .
Physical properties of copper:
 Crystal structure FCC
 Atomic number 29
 Atomic weight 63.546
 Density (g.cm-3) 8.933
 Melting point (oC) 1084.62
Coppers mechanical properties depend on its state and are defined by its lattice structure. Copper
has good formability and toughness at room temperature and also at reduced temperature.
Increasing the temperature steadily decreases coppers strength properties. Also at around 500 °C

2. the coppers technical plastic properties decrease. Due to this behavior, cold forming or hot
forming at 800 to 900 °C of copper is proper. Cold forming increases the strength properties but
results in ductility decreasing. In the as cast state, the copper has strength of 160 MPa. Hot
rolling increases coppers strength to 220 MPa. Copper has a good ductility and by cold
deformation it is possible to reach the strength values close to the strength values of soft steel.
a) temperature influence on tensile strength, yield value and ductility
b) change properties due to the cold forming
Fig. 3. Copper mechanical properties

3. Effect of various alloying elements
Classification of copper and copper alloys:
Copper and copper alloys are designated according to the Copper Development
Association (CDA):
 Wrought alloys
(C100-C799)
 Cast alloys
(C800-C999)
Copper alloys are identified by the Unified Numbering System (UNS) which categorizes families
of alloys based upon their elemental make-up. Wrought products range from UNS C10000
through UNS C79999; cast products are assigned numbers between UNS C80000 and UNS
C99999.

4. UNS alloy designation
Unalloyed Copper:
Copper in its pure, unalloyed state is soft, provides high electrical and thermal
conductivity and has excellent corrosion resistance. There are various grades of unalloyed
copper which differ in the amount of impurities they contain. Oxygen free grades are
used for high conductivity and ductility.
Cu-0xygen phase diagram

5. As cast oxygen free Cu Hot worked
Hot-worked oxygen free copper exposed to H2 at
850oC/0.5h

6. Brasses:
Brasses are alloys made from copper and zinc, they exhibit good strength and ductility
and are easily cold worked, properties which improve with increased zinc content up to
35%. Brass coloration ranges from red to golden yellow, depending on the amount of
zinc the alloy contains.Gilding Metal, Commercial Bronze, Jewelry Bronze, Red Brass
and Cartridge Brass are common names given to brass alloys with specific zinc contents.
Brasses containing between 32% and 39% zinc exhibit excellent hot working
characteristics but limited cold workability. Brasses containing more than 39% zinc, such
as Muntz Metal, have high strength and lower ductility at room temperature than alloys
with less zinc. Brasses are known for their ease of fabrication by drawability, high cold-
worked strength and corrosion resistance.
Brasses are routinely blanked, coined, drawn and pierced to produce springs, fire
extinguishers, jewelry, radiator cores, lamp fixtures, ammunition, flexible hose and the
base for
gold plate.
Cu-Zn phase diagram

7. Tin Brasses:
Tin Brasses are alloys made from copper, zinc (2% to 40%) and tin (0.2%-3%). This
family of alloys include admirality brasses, naval brasses and free-machining tin brasses.
These alloys are used to made high strength fastners, electrical connectors, springs,
corrosion resistant mechanical products, marine hardware, pumps shafts and corrosion
resistant screw machine parts. They provide increased corrosion resistance. They possess
good hot forgeability and good cold formability. These materials have moderate strength,
high atmospheric and aqueous corrosion resistance and excellent electrical conductivity.
Cu-Tin alloy phase diagram

8. Silicon Bronzes:
Silicon Bronzes are part of the subgroup of high-strength brasses. They contain less than
20% zinc and upto 6% silicon and are solid solution strengthened. Silicon red brasses are
used for valve stems where corrosion resistance and high strength are critical. Included in
this category are the silicon red bronzes, which are similar to silicon red brasses except
for their very low concentrations of zinc. They are used to make bearings, gears and
intricately shaped pump and valve components.
Cu-Silicon phase diagram
Nickel Silvers:
Nickel Silvers, also called nickel brasses, are alloy containing copper, nickel and zinc.
Though they do not contain silver, they have an attractive silver luster, moderately high
strength and good corrosion resistance. They are used to make food and beverage
handling equipmentt, decorative hardware, electroplated tableware, optical and
photographic equipment and musical instruments.

9. Copper Nickel:
Copper Nickel alloys contain anywhere from 2% to 30% nickel, are highly corrosion-
resistant and thermally stable. The addition of iron, chromium, niobium and/or
manganese can improve their strength and corrosion resistance in steam and moist air.
They are used to make electrical and electronic products, tubes for condensers in ships,
on offshore platforms and in power plants, and various other marine products including
valves, pumps, fittings and sheathing for ship hulls.
Phosphor Bronzes:
Phosphor Bronzes, or tin bronzes as they are sometimes called, contain between 0.5%
and 11% tin and 0.01% to 0.35% phosphorous. Tin increases their corrosion resistance
and tensile strength, phosphorus increases wear resistance and stiffness. They have super
spring qualities, high fatigue resistance, excellent formability and solderability.
TABLE : Compositions & Properties of the More Common Copper Alloys

10. Aluminum bronzes:
Aluminum Bronzes contain 6% to 12% aluminum, up to 6% iron and nickel and provide high
strength and excellent corrosion and wear resistance. Solid solution strengthening, cold work and
precipitation of an iron rich phase contribute to these characteristics. High aluminum containing
alloys can be quenched and tempered. Aluminum bronzes are used in marine hardware, shafts
and pump and valve components for handling seawater, sour mine waters, nonoxidizing acids,
and industrial process fluids. They are also used as heavy duty sleeve bearings and machine tool
ways. Aluminum bronze castings have exceptional corrosion resistance, high strength, toughness
and wear resistance. They also exhibit good casting and welding characteristics.
Cu-Al alloy phase diagram
Effect of Al on mech. Properties

11. Speciality copper alloys:
Specialty Copper Alloys, based, for example, on the copper-nickel-silicon and copper-nickel-tin
systems provide unique combinations of properties due to their intrinsic precipitation hardening
capability. Their high strength coupled with good formability, thermal stability and electrical
conductivity make them appropriate to use them in electrical and electronic connectors and
hardware.
As we have seen, copper and its alloys constitute a broad range of chemical compositions and are
employed widely in applications that enable and enhance our everyday lives. Each application
makes effective use of copper’s attributes: strength, conductivity, color, formability, joinability
and thermal stability.

12. Coppers Metals which have a designated minimum copper content of 99.3%or higher.
High
Copper
Alloys
For the wrought products, these are alloys with designated copper contents less than
99.3% but more than 96% which do not fall into any other copper alloy group.
The cast high copper alloys have designated copper contents in excess of 94%, to
which silver may be added for special properties.
Brasses
These alloys contain zinc as the principal alloying element with or without other
designated alloying elements such as iron, aluminum, nickel and silicon. The wrought
alloys comprise three main families of brasses: copper-zinc alloys; copper-zinc-lead
alloys (leaded brasses); and copper-zinc-tin alloys (tin brasses). The cast
alloys comprise four main families of brasses: copper-tin-zinc alloys (red, semi-red
and yellow brasses); "manganese bronze" alloys (high strength yellow brasses);
leaded "manganese bronze" alloys (leaded high strength yellow brasses); copper-
zinc-silicon alloys (silicon brasses and bronzes); and cast copper-bismuth and copper-
bismuth-selenium alloys. Ingot for remelting for the manufacture of castings may vary
slightly from the ranges shown.
Bronzes
Broadly speaking, bronzes are copper alloys in which the major alloying element is
not zinc or nickel. Originally "bronze" described alloys with tin as the only or principal
alloying element. Today, the term is generally used not by itself but with a modifying
adjective. Forwrought alloys, there are four main families of bronzes: copper-tin-
phosphorus alloys (phosphor bronzes); copper-tin- lead-phosphorus alloys (leaded
phosphor bronzes); copper-aluminum alloys (aluminum bronzes); and copper-silicon
alloys (silicon bronzes).
The cast alloys have four main families of bronzes: copper-tin alloys (tin bronzes);
copper-tin-lead alloys (leaded and high leaded tin bronzes); copper-tin-nickel alloys
(nickel-tin bronzes); and copper- aluminum alloys (aluminum bronzes).
The family of alloys known as "manganese bronzes," in which zinc is the major
alloying element, is included in the brasses, above.
Copper-
Nickels
These are alloys with nickel as the principal alloying element, with or without other
designated alloying elements.
Copper-
Nickel-Zinc
Alloys
Known commonly as "nickel silvers," these are alloys which contain zinc and nickel as
the principal and secondary alloying elements, with or without other designated
elements.
Leaded
Coppers
These comprise a series of cast alloys of copper with 20% or more lead, sometimes
with a small amount of silver, but without tin or zinc.
Special
Alloys
Alloys whose chemical compositions do not fall into any of the above categories are
combined in "special alloys."

13. Standard Chemical Composition Limits
The composition limits in this listing of Standard Designations for Copper and Copper Alloys
are presented according to the following numerical convention, wherever practicable.
Constituent Convention For Expressing Composition Limits
Copper Nos. C10000 - C15999 (wrought) and C80000 - C81199 (cast):
Copper XX.XX
Alloying elements and impurities:
1/10 and over .XX
1/100 and less than 1/10 .0XX
1/1000 and less than 1/100 .00X
less than 1/1000 .000X
Copper Alloy Nos. C16000 - C79999 (wrought) and C81300 - C99999 (cast):
Copper XX.X
Alloying elements and impurities:
6/10 and over .X
1/10 and less than 6/10 .XX

14. Constituent Convention For Expressing Composition Limits
Copper Nos. C10000 - C15999 (wrought) and C80000 - C81199 (cast):
1/100 and less than 1/10 .0X
1/1000 and less than 1/100 .00X
less than 1/1000 .000X
Temper designation:
Temper designation of copper alloys was developed by the American Society for Testing and
Materials (ASTM).
The designation system uses codes, consisting of a letter, indicating general temper, and
additional numbers and letters, specifying the temper parameters:
 O – annealed:
O10…O82 – various degrees of annealing;
OS005…OS200 – annealed to a specific grain size;
 M - as manufactured:
M01…M45 – manufactured by a specific method;
 H – cold worked:
H00…H14 – various degrees of cold work (hardness);
H50…H86 – cold work in specific process;
HR01…HR50 – cold work followed by stress relief;
HT04…HT08 – cold work followed by strengthening heat treatment;
 T - heat treatment followed by rapid cooling:
TB00 – solution treatment;
TD00…TD04 – solution treatment followed by cold work;
TF00 – solution treatment followed by precipitation hardening;
TL00…TL04 – precipitation hardening followed by cold work;

15. TR00…TR04 – precipitation hardening followed by cold work and stress relief;
TH00…TH04 – solution treatment followed by cold work and precipitation hardening;
TM00…TM008 – combination of cold work by rolling and precipitation hardening;
TQ00…TQ75 – hardening by quenching;
 W – welded:
WM00…WM50 – as welded;
WO – welded and annealed;
WH00...WH01 – welded and cold worked;
WR00…WR01 – welded, cold worked and stress relieved.